Multi-grooved channel design in continuous casting mold for enhancing heat transfer efficiency considering pressure drop and flow rate loss

Tianze Zhang, Zhaocheng Wei, Xueqin Wang, Xiuru Li, Minjie Wang
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Abstract

An efficient, speedy, multi-grooved (ESMG) mold was designed and manufactured for optimization to address issues such as low heat transfer rate, slow casting speed, and quality defects in traditional continuous casting molds. The flow resistance mechanism of multi-grooved channels with varying parameters was investigated by considering the ESMG geometric model, the convective heat transfer characteristic variation trends were revealed with different channel designs. Considering constraints of the dimensional chain and supply pressure, variation trends and mechanisms of the pressure drop, flow rate loss, and convective heat transfer coefficient of the ESMG mold were explored using multiple channel variables. Based on the numerical model of the ESMG channel, temperature variation trends in the copper mold were verified by comparison with relevant literature data, supporting the convective-heat-transfer model and variation trends of the ESMG mold. A high-efficiency heat-transfer ESMG assembly that casts U71Mn high-carbon large rectangular billets was fabricated, achieving a closed-loop dimensional chain and replacing traditional molds. Experimental validation on the continuous casting machine (CCM) proved directly that redesigning the ESMG mold cooling channel improved heat transfer efficiency and reduced CO emissions. After 504 h on the CCM, the ESMG mold casting speed increased from 1.1 to 1.6 m/min, the heat transfer efficiency was 17.6% higher than that of traditional molds and CO emissions were estimated to decrease by 31.2%. The billets produced by the ESMG mold had no quality defects in shape or surface with the original casting conditions, which provided enhanced support for accelerating continuous casting lines.
考虑到压降和流速损失,在连铸模中设计多沟槽以提高传热效率
针对传统连铸模具传热率低、浇铸速度慢和质量缺陷等问题,设计并制造了一种高效、快速、多沟槽(ESMG)模具,并对其进行了优化。通过考虑 ESMG 几何模型,研究了不同参数的多沟槽的流动阻力机理,揭示了不同沟槽设计的对流传热特性变化趋势。考虑到尺寸链和供应压力的限制,利用多沟槽变量探讨了ESMG模具的压降、流速损失和对流传热系数的变化趋势和机理。基于 ESMG 通道的数值模型,通过与相关文献数据的对比,验证了铜模的温度变化趋势,支持了 ESMG 模具的对流换热模型和变化趋势。制造出了浇铸 U71Mn 高碳大矩形坯的高效传热 ESMG 组件,实现了尺寸链闭环并替代了传统模具。连铸机(CCM)上的实验验证直接证明,重新设计的 ESMG 结晶器冷却通道提高了传热效率,减少了二氧化碳排放。在 CCM 上运行 504 小时后,ESMG 结晶器的浇铸速度从 1.1 米/分钟提高到 1.6 米/分钟,传热效率比传统结晶器高出 17.6%,二氧化碳排放量估计减少了 31.2%。在原始铸造条件下,ESMG 结晶器生产的坯料在形状和表面上没有质量缺陷,这为加快连铸生产线提供了更有力的支持。
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